LATCHING CLUTCH ASSEMBLY AND METHOD OF OPERATING THE SAME
A method of operating a friction plate clutch includes activating a clutch control mechanism to engage the friction plate clutch, and engaging a holding clutch. The clutch control mechanism is then deactivated, rendering it unable to maintain engagement of the friction plate clutch. The holding clutch is used to retain engagement of the friction plate clutch. One embodiment of the method uses a wedge clutch as the holding clutch, and another embodiment uses a one-way bearing clutch. The clutch control mechanism may be a hydraulic clutch control. A latching clutch assembly includes a friction plate clutch movable between an engaged and a disengaged position. A bearing clutch is operatively coupled to the friction plate clutch and has a locked and a released position. The locked position is configured to oppose movement of the friction plate clutch from the engaged position to the disengaged position.
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This disclosure relates to clutch assemblies for selectively transferring rotation between two or more bodies.
BACKGROUND OF THE INVENTIONPower transmissions, particularly multi-speed power transmissions of the automatic shifting type, utilize torque transmitting members or friction devices to transfer rotational movement and torque between transmission elements. One such torque transmitting member is the friction plate clutch, which enforces frictional engagement between interleaved disc elements formed in a friction pack, and alternately coupled with an input or output member. In some cases, the friction device is a brake and the output member is a stationary housing.
Torque transmitting mechanisms include a control mechanism, such as: fluid (hydraulic), mechanical, or electrical control mechanisms. Fluid-operated torque transmitting members have a piston disposed within a housing. The piston travels linearly in a cavity in the housing between an engaged position and a disengaged position, thereby causing selective engagement of the friction elements.
SUMMARYA method of operating a friction plate clutch is provided. The method includes activating a clutch control mechanism to engage the friction plate clutch, and engaging a holding clutch. The clutch control mechanism is then deactivated, such that the clutch control mechanism is unable to maintain engagement of the friction plate clutch. The holding clutch is used to retain engagement of the friction plate clutch. The method may further include reactivating the clutch control mechanism and disengaging the holding clutch, such that control over engagement of the friction plate clutch is returned to the clutch control mechanism.
One embodiment of the method uses a wedge clutch as the holding clutch. Another embodiment of the method uses a one-way bearing clutch as the holding clutch. The clutch control mechanism may be a hydraulic, or fluid-operated, clutch control.
A latching clutch assembly is provided. The latching clutch assembly includes a friction plate clutch which is movable between an engaged position and a disengaged position. A bearing clutch is operatively coupled to the friction plate clutch and has a locked position and a released position. The locked position of the bearing clutch is configured to oppose movement of the friction plate clutch from the engaged position to the disengaged position.
The above features and advantages and other features and advantages of the present invention are readily apparent from the following detailed description of the best modes and other embodiments for carrying out the invention when taken in connection with the accompanying drawings.
Referring to the drawings, wherein like reference numbers correspond to like or similar components throughout the several figures, there is shown in
Those having ordinary skill in the art will recognize that the input/output designation of the first and second members 12 and 16 is not limiting, and that the input/output nature of the two members may change during operation of clutch assembly 10. For example, in some hybrid transmission applications, the direction of rotation, and the input and output direction, may change as the operating modes of the hybrid transmission change. Furthermore, those having ordinary skill in the art will recognize that the specific orientation of the inner and outer hubs 14 and 18 are also not limiting, and that the first member 12 may have either an inner or outer hub attached thereto.
While the present invention is described in detail with respect to automotive applications, those skilled in the art will recognize the broader applicability of the invention. Those having ordinary skill in the art will recognize that terms such as “above,” “below,” “upward,” “downward,” et cetera, are used descriptively of the figures, and do not represent limitations on the scope of the invention, as defined by the appended claims.
The embodiments shown in the figures utilize fluid (hydraulic) operated clutch control mechanisms, but other clutch control mechanisms may be used within the scope of the appended claims. For example, without limitation, the clutch control mechanism may also be: electrical, mechanical or other control methods recognizable to those having ordinary skill in the art.
A clutch pack 20 is disposed within the clutch assembly 10 between the outer and inner hubs 14 and 18. Clutch pack 20 allows selective torque transfer between the outer hub 14 and the inner hub 18—and therefore between the first member 12 and the second member 16. The clutch pack 20 incorporates a plurality of clutch plates or discs 22 and a plurality or friction plates or discs 24. The clutch plates 22 are drivingly connected with outer hub 14 and the friction plates 24 are drivingly connected with inner hub 18. The clutch pack 20, and clutch assembly 10, is shown in
Slidably disposed in a cavity formed by the first and second members 12 and 16 and the outer and inner hubs 14 and 18, is a friction clutch piston 26. A friction clutch chamber 28 is defined between the friction clutch piston 26 and either, or both, the first member 12 and outer hub 14. Friction clutch chamber 28 is filled with a fluid, such as transmission fluid or oil, communicating with a main pressure source. The main pressure source may be, for example, without limitation: a transmission pump, a torque converter, or another pressure source recognizable to those having ordinary skill in the art. Therefore, the main pressure source feeding into the friction clutch chamber 28 acts as a hydraulic actuator for the fluid-operated clutch control mechanism.
The clutch assembly 10 further includes a return spring 30. The return spring 30 acts upon a reaction plate 32, which is forced into abutment with the friction clutch piston 26. Return spring 30 also acts upon a stationary return plate 34; however, in other embodiments, the return spring 30 could act directly upon the inner hub portion 18. Thus, the friction clutch piston 26 is urged leftward, as seen in
When there is no longer sufficient pressure from the main pressure source to retain engagement of the clutch plates 22 to the friction plates 24, the force of the return spring 30 will move the friction clutch piston 26 leftward, causing disengagement of the clutch pack 20. Thus, the fluid-operated clutch control mechanism provides the clutch pack 20 with two positions relating to the amount of pressure in the friction clutch chamber 28 and the opposing force of the return spring 30: a pressure set position (engaged, shown in
The availability of the main pressure source to operate the friction clutch piston 26 may be tied to the operation of the vehicle engine, such that while the engine is off, there may be insufficient pressure to engage, or maintain engagement of, the clutch pack 20. This may occur, for example, and without limitation, in hybrid vehicles or other vehicles which shut off the combustion engine during traffic stops. However, engagement of the clutch pack 20 may be desired during engine-off periods, or during engine re-starts.
Clutch assembly 10 includes a holding clutch mechanism configured to hold or maintain engagement of clutch pack 20 without the force provided by the main pressure source in the friction clutch chamber 28. The holding clutch mechanism used in clutch assembly 10 is a wedge clutch 40, which may be selectively engaged during periods of insufficient main pressure to maintain engagement of the clutch pack 20.
The wedge clutch 40 includes a wedge 42 and a wedge actuator 44. In the embodiment shown in
Those having ordinary skill in the art will recognize that while
By preventing leftward movement of the friction clutch piston 26, engagement of the wedge clutch 40 allows the clutch pack 20 to remain engaged even where there is no pressure in the friction clutch chamber 28. Engagement of wedge clutch 40 allows for common rotation of the first and second members 12 and 16 even when the vehicle engine is turned off and the main pressure source is not functioning.
After the fluid-operated clutch control mechanism is reactivated, and the main pressure source repressurizes the friction clutch chamber 28, the clutch pack 20 may again be held in engagement by the fluid-operated clutch control mechanism. Once the fluid force is sufficient, the friction load on the wedge 42 is decreased, and the wedge clutch 40 may be disengaged.
The wedge actuator 44 may disengage the wedge clutch 40 by moving the wedge 42 upward (as viewed in
The embodiment of the wedge clutch 40 shown in
Referring now to
Clutch assembly 110, and the clutch pack 20, is shown in
The friction clutch piston 26 is slidably disposed in a cavity formed by the first and second members 12 and 16 and the outer and inner hubs 14 and 18. The friction clutch chamber 28 is in fluid communication with the main pressure source.
In operation, to engage the clutch pack 20, as the pressure in the friction clutch chamber 28 is increased, the friction clutch piston 26 is biased rightward, such that it moves to the right and contacts the clutch pack 20. The fluid force from the friction clutch chamber 28 overcomes the force of the return spring 30 to move the friction clutch piston 26 to the right, locking the clutch plates 22 to the friction plates 24. Again, the main pressure source may be throttled or otherwise controlled to selectively vary the fluid force acting on the friction clutch piston 26.
Return spring 30 acts upon a reaction plate 132 which is fixedly attached to the friction clutch piston 26. Return spring 30 also acts upon a stationary return plate 34. The friction clutch piston 26 is urged leftward (as viewed in
Clutch assembly 110 further includes a holding clutch mechanism configured to hold or maintain engagement of clutch pack 20 without the force provided by the main pressure source in the friction clutch chamber 28. The holding clutch mechanism used in clutch assembly 110 is a bearing clutch 150, which may be selectively locked during periods of insufficient main pressure to hold or maintain engagement of the clutch pack 20.
As explained below, the bearing clutch 150 is configured such that, when locked, bearing clutch 150 will freely move to the right but is unable to move to the left (as viewed in
Bearing clutch 150 includes a bearing piston 152 which is slidably disposed between the reaction plate 132 and an outer surface 13 of the input member 12. A plurality of ball bearings or spheres 154 are disposed between the outer surface 13 and a cam surface 156 formed on an inner surface of the bearing piston 152. Spheres 154 may be disposed with equiangular spacing about the outer surface 13, and the number of spheres 154 may vary, but will usually include at least three. The spheres 154 are housed in a cage 158, and are urged rightward (as viewed in FIGS. 3 and 4,) relative to the bearing piston 152, by at least one tickler spring 160, which is compressed between the bearing piston 152 and the cage 158.
The cam surface 156 is formed such that rightward movement of the bearing piston 152 allows sufficient space to permit the spheres 154 to roll freely along the outer surface 13. However, when the tickler spring 160 is able to move the spheres 154 rightward into abutment with the cam surface 156, leftward movement of the bearing piston 152 is prevented by the locking reaction between the cam surface 156, the spheres 154 and the outer surface 13. Therefore, the bearing clutch 150 will move rightward freely but will prevent leftward movement unless the tickler spring 160 is neutralized. This is the locked state of the bearing clutch 150, and is shown in
A shoulder 162 is annular and aligned for contact with an annular locking ring 164 which is secured to the reaction plate 132. When the bearing clutch 150 is locked, the shoulder 162 and the annular locking ring 164 cooperate to prevent the reaction plate 132 from moving leftward. Therefore, the friction clutch piston 26 is also prevented from leftward movement. If the clutch pack 20 is in the engaged position, preventing leftward movement of the friction clutch piston 26 will prevent disengagement of the clutch pack 20, even without sufficient main pressure in the friction clutch chamber 28.
In order to disengage the clutch pack 20, the bearing clutch 150 must be released. To release the bearing clutch 150, the spheres 154 must be moved leftward, relative to the bearing piston 152, in order to relieve the spheres 154 of the locking force generated by contact with the cam surface 156.
Leftward movement of the spheres 154, relative to the bearing piston 152 and cam surface 156, is provided by a compensator piston 166, which is slidably disposed between the outer surface 13 and the reaction plate 132. In the embodiment shown, the compensator piston 166 selectively biases the cage 158, and therefore the spheres 154, leftward relative to the cam surface 156. Compensator piston 166 is in fluid communication with a compensator chamber 168, which is in fluid communication with a dam or compensator pressure source.
The compensator pressure source selectively provides fluid pressure which biases the compensator piston leftward (as viewed in
If the fluid force provided by the compensator chamber 168 is sufficient to overcome of the force of the compensator return spring 170, the compensator piston 166 will bias the spheres leftward, relative to the bearing piston 152, and release (disengage) the bearing clutch 150 (as shown in
When the bearing clutch 150 is released (as shown in
In operation of the clutch assembly 110, the compensator pressure source and the main pressure source may be derived from operation of the vehicle engine. If the clutch pack 20 is engaged and the engine is shut off, the loss of pressure to the friction clutch chamber 28 would cause the reaction spring 30 to attempt to disengage the clutch pack 20. However, loss of pressure to the compensator chamber 168 will lock the bearing clutch 150, such that the friction clutch piston 26 is not able to move leftward, and the engagement of the clutch pack 20 is maintained, even with little or no pressure being supplied by the main pressure source (to friction clutch chamber 28) or to the compensator pressure source (to the compensator chamber 168).
While the best modes and other embodiments for carrying out the claimed invention have been described in detail, those familiar with the art to which this invention relates will recognize various alternative designs and embodiments for practicing the invention within the scope of the appended claims.
Claims
1. A method of operating a friction plate clutch, comprising:
- activating a clutch control mechanism to engage the friction plate clutch;
- engaging a holding clutch;
- deactivating the clutch control mechanism, such that the clutch control mechanism is unable to maintain engagement of the friction plate clutch; and
- retaining engagement of the friction plate clutch with the holding clutch.
2. The method of claim 1, further comprising:
- reactivating the clutch control mechanism; and
- disengaging the holding clutch.
3. The method of claim 2, wherein the holding clutch is a wedge clutch.
4. The method of claim 3, wherein the clutch control mechanism is a hydraulic clutch control.
5. The method of claim 3, further comprising engaging and disengaging the wedge clutch with the clutch control mechanism.
6. The method of claim 5, further comprising:
- deactivating a vehicle engine after engaging the wedge clutch; and
- reactivating the vehicle engine before reactivating the clutch control mechanism.
7. The method of claim 2, wherein the holding clutch is a one-way bearing clutch.
8. The method of claim 7, wherein the clutch control mechanism is a hydraulic clutch control, and activating the hydraulic clutch control includes pressurizing a hydraulic actuator and deactivating the hydraulic clutch control includes depressurizing the hydraulic actuator.
9. The method of claim 8, wherein pressurizing the hydraulic actuator and disengaging the one-way bearing clutch occurs via a common pressure source.
10. The method of claim 9, wherein the common pressure source is a main transmission pump driven by a vehicle engine.
11. The method of claim 10, further comprising:
- deactivating the vehicle engine after engaging the one-way bearing clutch; and
- reactivating the vehicle engine before reactivating the hydraulic actuator.
12. A latching clutch assembly, comprising:
- a friction plate clutch movable between an engaged position and a disengaged position; and
- a bearing clutch operatively coupled to said friction plate clutch and movable between a locked position and a released position, wherein said locked position of said bearing clutch is configured to oppose movement of said friction plate clutch from said engaged position to said disengaged position.
13. The latching clutch of claim 12, further comprising:
- a first pressure source in fluid communication with said friction plate clutch, wherein said friction plate clutch is biased toward said engaged position by said first pressure source; and
- a second pressure source in fluid communication with said bearing clutch, wherein said bearing clutch is configured to be biased toward said released position by said second pressure source.
14. The latching clutch of claim 13, wherein said bearing clutch further includes a compensator piston disposed in fluid communication with said second pressure source and configured to bias said bearing clutch toward said released position.
15. The latching clutch of claim 14, wherein said second pressure source is configured to be disabled substantially simultaneously with said first pressure source.
16. A latching clutch assembly, comprising:
- a friction plate clutch movable between an engaged position and a disengaged position; and
- a wedge clutch operatively coupled to said friction plate clutch and movable between an engaged position and a disengaged position, wherein said engaged position of said wedge clutch is configured to oppose movement of said friction plate clutch from said engaged position to said disengaged position.
17. The latching clutch of claim 16, further comprising:
- a first pressure source in fluid communication with said friction plate clutch, wherein said friction plate clutch is biased toward said engaged position by said first pressure source; and
- an actuator operatively connected to said wedge clutch, wherein said actuator is configured to move said wedge clutch between said disengaged position and said engaged position.
18. The latching clutch of claim 17, further comprising:
- a clutch hub; and
- a clutch piston, wherein said wedge clutch is configured to be disposed between said clutch housing and said clutch piston when said wedge clutch is in said engaged position.
19. The latching clutch of claim 18, wherein said actuator is in fluid communication with said first pressure source, and said first pressure source is configured to move said wedge clutch between said disengaged position and said engaged position.
Type: Application
Filed: Jan 12, 2009
Publication Date: Jul 15, 2010
Patent Grant number: 8172058
Applicant: GM GLOBAL TECHNOLOGY OPERATIONS, INC. (Detroit, MI)
Inventors: Edwin T. Grochowski (Howell, MI), Chi-Kuan Kao (Troy, MI)
Application Number: 12/351,901
International Classification: B60W 10/02 (20060101); F16D 13/04 (20060101);